Upload
others
View
11
Download
0
Embed Size (px)
Citation preview
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1456
Original Research Article https://doi.org/10.20546/ijcmas.2019.802.169
Integrating Soil Solarization and Seed Biopriming to Manage
Seedling Damping-Off in Flower Nurseries
Deepa Khulbe*
Regional Research & Technology Transfer Station (Coastal Zone), Orissa University of
Agriculture & Technology, Bhubaneswar, India
*Corresponding author
A B S T R A C T
Introduction
Most horticultural corps are raised from seeds
in nurseries and then transplanted.
Susceptibility to a wide range of soil borne
pathogens capable of surviving for long
periods of time in soil or plant debris is
threatening to cultivation of these crops.
Damping-off is the most serious problem
encountered in raising nursery seedlings
caused by over a dozen genera of various soil-
borne fungi including Rhizoctonia, Fusarium,
International Journal of Current Microbiology and Applied Sciences ISSN: 2319-7706 Volume 8 Number 02 (2019) Journal homepage: http://www.ijcmas.com
The effect of soil solarization for a month in integration with seed biopriming with
Trichoderma harzianum and Pseudomonas fluorescens and seed treatment with fungicides
was studied in two flower crop nurseries of calendula and aster, raised in succession.
Nursery beds were solarized for 30 days using polyethylene sheet of three colours viz.
transparent white, black and red; and three thicknesses (50G, 200G and 400G). The
damping-off incidence in first crop (Calendula) was minimum (28.6 per cent) in plots
solarized with 400 gauge white polyethylene 8in combination with Vitavax seed treatment
as compared to the 89.5 per cent damping-off in non-solarized control plots. An increase
of 10-12 o
C in average weekly soil temperature was recorded in solarized soil with
maximum soil temperature ranging between 50-54oC in soil mulched with white or red
polyethylene sheet. The effect of solarization lasted even after 60 days of solarization as
the damping-off incidence in second nursery crop too was minimum (30.0%) in plots
solarized with 400 gauge white polyethylene in combination with biopriming with P.
fluorescence as compared to the 63.6 per cent damping off in non-solarized control plots.
The performance of soil solarization with polyethylene sheets of different colours and
thickness were at par in terms of reduction of damping off in aster. Significant increase in
the seedling growth was observed due to the soil solarization in all the treatments. Highest
shoot length (16.50 cm) was observed in treatment involving solarization with 400 gauge
polyethylene sheet in combination with Vitavax seed treatment, in calendula, as compared
to the 3.3 cm shoot length in non-solarized control plots. Growth promontory effect of
solarization was also observed in second nursery crop aster. Highest shoot length (2.8 cm)
was observed in treatment involving solarization with 50 gauge polyethylene sheet in
combination with no seed treatment.
K e y w o r d s
Floriculture
nursery,
Solarization,
Damping-off,
Polyethylene
thickness, Seed
biopriming
Accepted:
12 January 2019
Available Online:
10 February 2019
Article Info
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1457
Sclerotium and fungal-like organisms
belonging to oomycetes (species of Pythium
and Phytophthora) and some other seed-borne
fungi (1). Damping off of seedlings is
reported to affect up to 5 to 80% of the
seedlings and thereby induce heavy economic
losses and once established in the nursery
soil, damping-off pathogens are able to
survive in the soil for many years, even in the
absence of host plants, either as saprophytes
or as resting structures that are capable of
surviving the adverse conditions (22, 25).
Nursery health is of immense importance for
profitable and sustainable cultivation of
flower crops, through the production of
healthy seedlings. It is well recognized that
due to seed rots, seedling rot and damping-
off, considerable plant population is lost
causing loss of seed, the high value input, in
case of many horticultural and ornamental
crops and also the indirect cost of replanting.
To produce healthy seedlings, soil health
plays an important role, however none of the
disease management techniques available
presently, could bring the level of soil
sanitation above critical threshold, where it
could reduce seed and seedling diseases (7,
21, 32, 37). The routine sanitation approaches
and soil sterilization / disinfestation with
fumigants or non-fumigant chemical
disinfectants posing environmental hazards,
are not compatible with sustainable
agriculture (6, 17). Soil solarization is a very
simple and low-cost sustainable technique
harnessing solar energy for managing soil
borne diseases that improves soil health
especially in nurseries and requires no special
scientific know-how (19). This technique is
useful for managing a wide spectrum of soil-
borne pests including fungi, bacteria,
nematodes, weeds and insects in growing
horticultural and floricultural crop nurseries,
which has become a remunerative venture
now a days (5, 15, 20, 27, 38).
Soil solarization is a process to capture the
solar radiations/energy for hydrothermal
heating of soil layers resulting in direct
thermal inactivation of pathogen propagules,
enhanced soil microbial antagonism and
improved plant growth response. For
management of soil borne pathogens and
pests, soil solarization has been accepted
worldwide as an eco-friendly alternative to
chemical soil disinfestation/ fumigation which
poses serious adverse effects on soil, water
and air. Hence, it is the most suited
technology for non-chemical soil
disinfestation and as a component of IPM in
horticultural nurseries (10, 20, 34, 21)
With this context, the study was conducted to
assess the efficacy of soil solarization for a
month in integration with seed bio-priming
with Trichoderma harzianum and
Pseudomonas fluorescens and seed treatment
with fungicides in calendula and aster nursery
beds on the incidence of damping-off of
seedlings and seedling growth following
single event of soil solarization using
polyethylene sheet of three different (white
transparent, black and red) colours and
thickness (50 gauge, 200 gauge and 400
gauge).
Materials and Methods
The study was carried out at G. B. Pant
University of Agriculture and Technology,
Pantnagar, India located at 29°N and 73.3°E
and an altitude of 243.84m above the mean
sea level agroclimatically falling under humid
sub-tropical zone located at foothills of South
Shivalik Ranges of the Himalayas. The soil of
the experimental site was clay loam soil with
soil pH 6.8 which was used for raising
nurseries of different annual and biennial
flowers for several years. The experiment was
laid in split plot design with three replications
with three polyethylene sheet colours viz.
white transparent, black and red, taking three
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1458
polyethylene thicknesses viz. 50 gauge, 200
gauge and 400 gauge as main plot factor and
five treatments including four seed treatments
and one control as sub-plot factors. Five
treatments given in each sub-plot included
seed biopriming with Trichoderma harzianum
and Pseudomonas fluorescens @ 4g per kg
seed and treatment with Thiram and Vitavax
@ 2.5g per kg seed and non-treated control
(Table 1). The bioagents Pant Bioagent-1
(Trichoderma harzianum) and Pant Bioagent-
2 (Pseudomonas fluorescens) were procured
from Biocontrol Laboratory, Department of
Plant Pathology, G. B. Pant University of
Agriculture and Technology, Pantnagar.
For solarization of nursery soil, raised beds
were prepared, irrigation was given to ensure
optimum soil moisture (at field capacity) and
beds were covered with polyethylene sheets
of three different colours and thickness. The
polyethylene sheets were buried into the soil
from all sides of the nursery beds (Fig 1) to
avoid moisture loss and any leakage of
trapped heat for effective solarization during
summer months for 30 days (2nd
July- 5th
Aug, 1999). Daily soil temperature during the
entire period of solarization was recorded by
placing soil-thermometers beneath the
polyethylene film at depth of 5cm. The
maximum daily temperatures were recorded
at 2.30 P.M. and finally weekly average
maximum temperature was computed.
After solarization, the polyethylene sheets
were removed and the nursery of calendula
was raised on solarized beds for 30 days and
after that aster nursery was raised in the same
beds in succession. To evaluate the effect of
solarization on the incidence of damping-off,
number of seeds expected or likely to
germinate i.e., germination per cent (X),
number of seeds actually germinated after 7
days of sowing (A) were counted using a
telecounter. Damping-off incidences were
computed by the following mathematical
formula given bellow.
The plant growth response was assessed in
terms of seedling shoot length and fresh
seedling shoot weight. Seedling shoot length
was recorded for seedlings uprooted at 30
days after sowing for 10 seedlings and
average calculated. Fresh shoot weight was
also recorded for the same 10 seedlings. The
data so obtained, were subjected to statistical
analysis and the mean values of three
replications were presented in data tables.
Results and Discussion
Effects of soil solarization on soil
temperature
Hydrothermal heating of soil layers is the
major principle of soil solarization. When wet
soil is mulched with polyethylene film, the
heat/ solar radiations that penetrate the film
are not allowed to be dissipated and lost.
Covering of the soil with polyethylene,
particularly the droplets that appear over the
under-surface of the plastic sheet, ensures
conservation of trapped heat. Thus, as per
changes in the daily cycles of sunshine and
darkness, the temperature status of the
solarized soil also changes. It was observed
that the temperature of the solarized soil, on
an average, increased every week by about l0-
12oC as the soil temperature ranged between
50-54oC in soil mulched with white or red
polyethylene sheet. The increase in soil
temperature of the soil mulched with black
sheet did not increase to the extent observed
with white and red sheet. The increase was
about 2-4oC over the temperature under un-
mulched soil. The thickness of the
polyethylene mulches did not cause any
significant change in the soil temperature (Fig
2a). The average soil temperature (at 5 cm
depth) under all three colours was almost
similar with all the thickness (Fig 2b).
Per cent incidence of seedling damping-off
= (X-A) x 100
A
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1459
Maximum soil temperature of 54oC was
recorded with white transparent polyethylene
sheet of 200G thickness as compared to
39.5oC in non-solarized soil. It was 52
oC with
red polyethylene sheet of 200G thickness
however, in case of black polyethylene sheet,
the maximum soil temperature of 42.2oC was
recorded with 50G thickness. Maximum
increase in soil temperature observed under
white transparent, red and black polyethylene
sheet was 12.9oC, 10.7
oC and 1.7
oC
respectively. Soil solarization additionally
suppressed the weed population too, as
compared to non-solarized plots as reported
by Campiglia et al., (4). Except Cyperus
rotundus almost all weed species were killed
by soil solarization (Fig. 3b).
The success of solarization is based on the
fact that most plant pathogens and pests are
mesophilic (20°C - 45°C), i.e. they are
typically unable to grow at temperatures
above 32°C. These soil borne pests are killed
directly or indirectly by the temperatures
achieved during solarization of the moist soil
under transparent plastic films which greatly
restrict the escape of volatiles gases and water
vapours (12, 20). However, thermo-tolerant
and thermophilic soil microflora (both
inhabitants and invaders) usually survive the
soil solarization process (20, 29, 34). Soil
solarization is reported to elevate the soil
temperature by 6-10°C in 0-20 cm soil profile
(3, 8, 13). Direct hydrothermal inactivation of
pathogen propagules as a consequence of
raised soil temperature has been reported to
have most pronounced lethal effects on a
broad spectrum of soil organisms (14, 23, 24,
34). Accumulation of heat effect above a
critical temperature threshold (about 37°C)
over time becomes lethal for mesophylic
organisms. However, other soilborne
organisms, if not directly inactivated by heat,
may be weakened and become vulnerable to
gases produced in solarized soil or to change
in microflora and thus are
managed/suppressed by one or other form of
biocontrol (16, 19, 30, 36). The thermal
decline of soilborne organisms during solar
heating depends on both, the soil temperatures
and exposure time which are inversely
related.
Invariably higher temperature was recorded
under white transparent mulch followed by
red and black mulches with high temperature
range and high soil heat flux distribution
under transparent and red mulches as
compared to black mulch which was strongly
skewed toward lower values (2). It was
concluded that heat flux is one of the
components of the energy balance and is
closely related to the amount of radiation
transmitted through mulches. Widespread
application of low density polyethylene
(LDPE) for agricultural mulching has been
advocated because of its flexibility, tensile
strength and resistance to physical damage
and polyethylene has been emphasized as an
ideal film for solar heating of soil as it is
essentially transparent to solar radiation (280
to 2500 nm), extending to the far infra red,
but much less transparent to terrestrial long
wave radiation (5000-35000 nm), and thus
reducing the escape of heat from the soil (7).
The heating efficacy of different types of
polyethylene is associated with its relative
transmittance.
Effect of solarization and seed biopriming
on seedling damping-off incidence
Soil solarization for a month using three
colours (White transparent, red and black) and
thickness of polyethylene (50, 200 and 400
gauge) in integration with seed biopriming
with Trichoderma harzianum and
Pseudomonas fluorescence, in flower crop
nurseries of calendula and aster raised in
succession in same plot, significantly reduced
the incidence of damping-off of seedlings
(Table 2 and 3). In calendula, significant
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1460
reduction in the incidence of damping-off was
recorded with seed treatments and solarization
separately and also in integration. In non-
solarized plots, despite seed-treatment with
fungicides or bioagent, the incidence of
damping-off ranged from 64.8 to 81 per cent
in calendula and from 51.5 to 56.9 per cent in
aster. In plots solarized with white
polyethylene, the incidence of damping-off
reduced to the level of 29.8- 35.8 per cent
however with black polyethylene sheet it
ranged between 55.5 to 69.2 per cent and
from 38.7 to 48 per cent with red
polyethylene sheet in calendula. In case of
aster, in plots solarized with white
polyethylene, the incidence of damping-off
reduced to the level of 35.0- 50.7 per cent,
with black polyethylene sheet from 40.5 to
59.5 per cent and with red polyethylene sheet
from 38.7 to 48 per cent.
Solarization with white transparent
polyethylene of all the three thicknesses (50
gauge, 200 gauge and 400 gauge),
significantly reduced the incidence of
damping-off of seedlings in calendula.
Percent increase in seedling emergence over
control due to solarization ranged from 13.9
to 55.2 in calendula and from 0.5 to 18.9 in
aster (Fig. 4) in solarized plots, even without
seed-treatments. Gasoni et al., (18) also
reported positive effect of soil solarization
and biocontrol agents on plant stand and
yield. Seed-treatment with bioagent or
fungicides further enhanced the effects of
solarization. It clearly indicated the efficacy
of soil solarization in integration with
chemical seed treatment and biopriming.
Solarization was most effective with white
transparent polyethylene (thickness 50, 200
and 400 gauge) as the incidence of damping-
off was reduced significantly to the level of
28.8 per cent compared to 39.7 per cent with
black PE-sheet and 37.7 per cent with red
polyethylene sheet (Table 2). The damping-
off incidence in calendula nursery crop was
minimum (28.8 per cent) in plots solarized
with 50 gauge white polyethylene in
combination with Vitavax seed treatment as
compared to the 89.5 per cent damping off in
non-solarized control plots. Soil solarization
with white polyethylene was significantly
better than with black and red polyethylene in
terms of reduction of damping off in
calendula.
In case of aster nursery, incidence of
damping-off was minimum (30.0%) in plots
solarized with 400 gauge white polyethylene
+ bio-priming with P. fluorescence as
compared to the 63.6 per cent damping off in
non-solarized control plots. However, it was
recorded minimum (38.3%) with 200G black
PE sheet and (40%) with 200G red PE sheet.
The overall performance of soil solarization
with transparent white polyethylene was
significantly superior in reducing the damping
off incidence however, as compared to black
or red PE sheet.
The data recorded for seedling damping-off
revealed significantly lower incidence of
damping off under white transparent
polyethylene sheet. Similarly significant
decrease was reported in the incidence of
damping-off in case of tomato, cauliflower
and onion raised in nurseries and integration
of solarization with seed treatment with
fungicides like Thiram etc. and biocontrol
agents further improved control of damping-
off of seedling as reported by Minuto et al.,
(26) and Mishra (28).
Solarization with white transparent PE sheet
increased the seedling emergence in calendula
up to 612% over control and up to 130.6%
over control in aster raised in same solarized
beds in succession (Fig 4). The per cent
increase in seedling emergence over control
was assessed 272.6% and 371.3% with black
and red PE sheet respectively, in calendula
and 120.3% and 137% in aster nursery.
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1461
Effect of solarization and seed biopriming
on seedling growth
Significant increase in the seedling growth
was observed due to the soil solarization in all
the treatments. In calendula, highest shoot
length (16.5cm) was observed in treatment
involving solarization with 400 gauge
polyethylene sheet +Vitavax seed treatment,
as compared to the 3.3 cm shoot length under
non-solarized control plots (Table 4). In aster
nursery, significant effect of solarization was
observed with white transparent polyethylene
and highest shoot length (2.87 cm) was
observed in treatment involving solarization
with 50 gauge PE sheet even without any seed
treatment. However, in plots solarized with
black and red PE sheets, improvement in
seedling length was statistically non-
significant (Table 5).
Table.1 Details of the seed treatments / biopriming agents and their rates of application
Fungicide / Bioagent Chemical / Agent Name Rate of Application
Dithiocarbamate Thiram 2.5 g/kg seed (0.25%)
Carboxin Vitavax 2.0 g/kg seed (0.20%)
T. harzianum Pant Bioagent-1(PB-1) of 1.5 x l09c.f.u 4.0 g/kg seed (0.4%)
P. fluorescens Pant Bioagent-2 (PB-2) of 1.5 x
l09c.f.u
4.0 g/kg seed (0.4%)
Table.2 Effect of soil solarization in integration with seed-biopriming on incidence of seedling
damping-off in calendula
Treatments Non-
solarize
d
Solarized
White Polyethylene Black Polyethylene Red Polyethylene
50G 200G 400G Mean 50G 200G 400G Mean 50G 200G 400G Mean
Control 89.5 34.
3
36.
0
37.9 36.1 75.6 67.5 71.0 71.
3
55.1 62.3 65.
7
61.0
Thiram 81.0 31.
0
33.
0
38.3 34.1 39.7 63.8 74.2 69.
2
49.7 44.7 48.
9
47.7
Vitavax 76.3 28.
8
31.
6
28.9 29.8 61.7 51.0 53.9 55.
5
40.6 38.0 37.
7
38.7
T. harzianum 76.1 29.
5
29.
5
30.4 35.8 64.3 57.3 64.4 62.
0
51.0 50.5 42.
5
48.0
P. ftuorescens 64.8 38.
6
38.
3
30.4 35.8 64.3 57.3 64.4 62.
0
51.0 50.5 42.
5
48.0
Main plot
mean
77.5 32.
5
33.
7
33.2 33.1 67.0 59.3 63.6 63.
3
48.1 49.9 48.
9
49.0
CD at 5%
CD1 = 4.06
CD2 = 5.64
CD3= 11.3
CD4 =10.8
CD1 - 4.30
CD2 - 7.95
CD3= 15.91
CD4 = 14.80
CD1 = 7.60
CD2 = 6.31
CD3 = 12.6
CD4 = 13.5
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1462
Table.3 Effect of soil solarization in integration with seed bio-biopriming on incidence of
seedling damping-off in aster
Treatments Non-
solarize
d
Solarized
White polyethylene Black polyethylene Red polyethylene
50G 200G 400G Mean 50G 200G 400G Mean 50G 200G 400G Mean
Control 63.6 52.1 50.3 55.1 52.5 56.4 58.5 63.1 59.3 52.1 53.7 54.7 53.5
Thiram 56.9 52.9 49.6 49.7 50.7 55.3 62.8 60.6 59.5 53.0 49.8 46.7 49.8
Vitaavax 56.3 49.3 41.2 40.0 43.5 47.2 51.2 46.3 46.2 50.0 42.1 47.6 46.6
T. harzianum 56.9 46.3 35.8 40.0 40.7 39.3 38.3 44.1 40.5 43.8 44.9 42-8 43.8
P. fluorescens 51.5 36.9 38.2 30.0 35.0 42.1 44.9 43.7 43.5 48.2 40.0 40.2 42.8
Main plot mean 57.0 47.5 43.0 42.9 44.5 48.1 51.1 51.6 50.2 49.4 46.1 46.4 47.3
CD at 5%
CD1 = 10.1
CD2 = 11.4
CD3 = 22.8
CD4 = 22.7
CD1 = 14.94
CD2 = 8.62
CD3 = 17.23
CD4 = 21.38
CD1 = 7.40
CD2 = 9.90
CD3 = 19.8
CD4 = 19.1
* Details of CD values
CD1= for comparing main plot means
CD2 = for comparing sub-plot means
CD3 = for comparison between two sub-plot means at same level of main plot
CD4 = for comparison between main plot means at same or different levels of sub-plot
Table.4 Effect of soil solarization and its integration with seed-biopriming on seedling shoot
length (cm) of calendula (each value is average of 10 readings)
Treatments Non-
Solarize
d
Solarized
White polyethylene Black polyethylene Red polyethylene
50G 200G 400G Mean 50G 200G 400G Mean 50G 200G 400G Mean
Control 3.30 10.50 11.51 12.07 11.36 4.96 6.01 5.47 5.48 8.00 7.00 7.53 7.51
Thiram 3.42 12.80 12.90 14.60 13.43 8.05 7.73 7.18 7.65 8.70 8.90 9.46 9.02
Vitavax 4.62 14.70 14.60 16.50 15.26 6.94 8.96 8.12 8.00 9.96 10.20 10.91 10.35
T. harzianum 4.47 13.30 14.80 13.40 13.80 9.14 7.91 9.20 8.75 9.20 10.70 10.43 10.11
P. fluorescens 4.45 12.05 14.50 13.50 13.50 10.0 9.20 8.50 9.23 9.20 9.80 10.40 9.80
Main plot
mean
4.05 12.60 13.80 14.20 13.47 7.83 7.96 7.70 7.83 9.00 9.30 9.75 9.35
CD at 5% CD1 = 1.24 CD1 = 1.42 CD1 - 1.47
CD2 - 1.09 CD2 = 0.97 CD2 = 0.85
CD3 = 2.17 CD3= 1.93 CD3 = 1.70
CD4 = 2.30 CD4 = 2.23 CD4 = 2.11
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1463
Table.5 Effect of soil solarization and its integration with seed-biopriming on seedling shoot
length (cm) of aster
Treatments Non-
Solarized
Solarized
White polyethylene Black polyethylene Red polyethylene
50G 200
G
400G Mean 50G 200G 400G Mean 50G 200G 400G Mean
Control 1.16 2.87 2.71 2.47 2.68 1.54 1.33 1.36 1.41 1.64 1.86 1.97 1.80
Thiram 1.80 2.16 2.20 2.40 2.25 1.64 1.66 1.71 1.67 1.96 2.00 2.37 2.11
Vitavax 1.62 2.30 2.47 2.48 2.41 2.00 1.83 1.85 1.89 2.09 1.98 2.00 2.02
T. harzianum 1.85 2.60 2.33 2.36 2.43 1.7 2.09 2.57 2.14 2.37 2.30 2.40 2.35
P. fluorescens 1.81 2.20 2.65 2.30 2.38 2.10 2.16 2.41 2.22 2.13 2.36 2.52 2.33
Mean 1.62 2.42 2.47 2.40 2.43 1.81 1.81 1.98 1.86 2.04 2.10 2.25 2.13
CD at 5%
CD1 = 0.56 CD1 =0.31 CD1 = 0.49
CD2 = 0.40 CD2 =0.35 CD
2 = 0.39
CD3 = 0.81 CD
3 =0.70 CD
3 = 0.76
CD4 = 0.91 CD
4 =0.69 CD
4 = 0.86
Table.6 Effect of soil solarization and its integration with seed-biopriming on fresh seedling (10
seedlings) shoot weight (g) of calendula
Treatments Non-
Solarized
Solarized
White polyethylene Black polyethylene Red polyethylene
50G 200G 400G Mean 50G 200G 400G Mean 50G 200G 400G Mean
Control 1.79 3.80 4.10 4.50 4.13 1.73 2.37 2.55 2.21 2.71 2.85 3.20 2.92
Thiram 2.12 5.30 4.97 5.00 5.09 2.63 2.63 3.01 2.75 2.95 3.07 3.45 3.15
Vitavax 1.91 4.90 4.80 5.32 5.00 2.71 2.96 2.76 2.81 3.16 3.33 3.51 3.33
T. harzianum 1.70 4.70 5.00 4.40 4.70 3.53 3.41 3.40 3.44 3.54 3.75 3.62 3.63
P. fluorescens 1.87 4.00 4.77 4.90 4.55 3.44 3.35 3.45 3.45 3.38 3.68 3.82 3.62
Main plot mean 1.87 4.50 4.74 4.80 4.68 2.81 2.94 3.03 2.93 3.15 3.33 3.52 3.33
CD at 5%
CD1= 0.63
CD2 = 1.56
CD3 = 0.47
CD4 = 1.10
CD1 = 0.23
CD2 = 0.43
CD3 = 0.87
CD4-0.81
CD1 = 0.47
CD2 = 0.35
CD3= 0.71
CD4 = 0.78
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1464
Table.7 Effect of soil solarization and its integration with seed-biopriming on fresh seedling (10
seedlings) shoot weight (g) of aster
Treatments Non-
Solarized
Solarized
White polyethylene Black polyethylene Red polyethylene
50G 200G 400G Mean 50 G 200G 400G Mean 50G 200G 400G Mean
Non treated 5.8 10.2 10.0 11.6 10.6 8.5 9.9 9.7 9.4 11.1 10.1 13.3 11.5
Thiram 7.2 12.4 10.5 12.5 11.8 8.6 13.1 13.2 11.6 12.1 13.5 14.2 11.7
Vitavax 8.1 13.0 12.0 13.2 12.7 9.2 12.2 12.7 11.3 14.3 11.4 13.2 12.5
T. harzianum 9.4 13.4 13.1 13.3 13.2 10.7 15.0 10.6 11.9 13.4 14.4 15.0 13.1
P. fluorescens 8.8 14.2 14.8 13.7 14.2 10.3 13.4 13.5 12.4 13.1 14.4 15.6 13.0
Mean 7.8 12.6 12.1 12.8 12.5 9.34 12.7 11.9 11.3 12.9 12.8 16.2 12.3
CD at 5% CD1=1.56
CD2=1.31
CD3=2.63 CD4=2.81
CD1=2.20
CD2=2.28
CD3=4.57 CD4=4.63
CD1=1.78
CD2=2.10
CD3=4.20 CD4=4.15
Fig.1 Steps involved in polyethylene sheet covering of the nursery beds
Step 1
Step 2
Step 3
Step 4
Step 5
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1465
Fig.2a Changes in soil temperature during four weeks of solarization
Fig.2b Effects polyethylene thickness on soil temperature
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1466
Fig.3 Solarization of nursery beds
(a) Solarization of nursery beds (b) White transparent polyethylene
(c) Red polyethylene (d) Black polyethylene
Fig.4 Per cent increase in seedling emergence over control
Nursery bed solarization also improved
seedling fresh weight in both the nurseries. In
case of calendula, maximum fresh shoot
weight of seedlings (5.3g) was recorded in
plots solarized with 50 gauge white
transparent PE sheet with Thiram seed
treatment followed by 4.9 g with Vitavax seed
treatment and 4.7g with T. harzianum
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1467
biopriming. The effect of seed priming with
T. harzianum and P. fluorescens was
significantly at par. Solarization with black
and red PE sheet too significantly improved
the fresh shoot weight for main plot factor,
the thickness of the PE sheet as well as for the
sub plot factor i. e. seed treatment
/biopriming. The fresh shoot weight of
seedlings improved to the tune of 3.45g
(biopriming with P. fluorescens) with 400G
black PE sheet and 3.75g (biopriming with T.
harzianum) with 200G red PE sheet (Table 6).
In aster, it was recorded maximum (14.8g) in
case of plots solarized with 200 gauge white
transparent PE sheet+ seed biopriming with P.
fluorescens followed by solarization with WT
PE+ seed biopriming with T. harzianum as
against 5.8g in non solarized control plots.
Although higher values of fresh shoot weight
as compared to non solarized control were
recorded in plots solarized with black and red
PE sheet, the effect of solarization was
statistically non-significant (Table 7). The
improved seedling growth response may be
attributed to increased concentration of
soluble mineral nutrients generally reported in
solarized soil (11, 19, 33, 34, 35) prevalently
due to the death and degradation/
decomposition of soil microbiota killed by the
heat treatment. Integration of soil solarization
with biofungicides has been reported to
manage several soilborne pathogens (7, 9, 31,
38).
It is concluded in the present study, soil
solarization with polyethylene sheet of
different thickness and colour of the
polyethylene film, showed significant
reduction in incidence damping off and
improvement in plant growth response of two
ornamental crops; calendula and aster.
Increased availability of plant nutrients is
reported to contribute to marked increase in
the growth, development, and yield of plants
grown in solarized soil. Soil solarization is
reported to increase soil electrical
conductivity indicating higher availability of
nutrients leading to relative increase in
populations of rhizosphere competent
bacteria, such as Bacillus spp. which
contributed to the marked increase in the
growth in solarized soil (34).
Soil solarization is an eco-friendly technique
to manage soilborne pests, to maintain healthy
crops and to preserve the environment
through effective use of solar energy.
Extensive research in past few decades has
shown that the color and thickness of
polyethylene sheet used for solarization may
be taken into consideration to increase the
efficiency of solarization and emphasis must
be to adopt the technology as an integral
component of crop production systems. In
case of flowers where seed is a high value
input, nursery disease management is of
prime importance. In view of growing
concerns towards conserving natural
resources and residual toxicity of hazardous
chemical pesticides, soil solarization proves
to be an absolute technology in integration
with seed bio-priming to combat soilborne
plant pathogens in a sustainable manner with
no harmful effects on soil and environment.
Therefore, sustainable and eco-friendly
technologies like soil solarization and seed
biopriming must be given due weightage
either alone or in integration, for nursery
disease management in high value crops like
ornamentals and vegetables
Acknowledgement
The financial assistance and necessary
facilities provided by G.B. Pant University of
Ag. & Tech., Pantnagar, India, for conducting
the study are duly acknowledged.
References
1. Agrios G. N. (2005). Plant Pathology. pp
410-427, 5th ed. Elsevier Academic Press.
2. Alkayssi A.W. and Alkaraghouli A.A. 1991.
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1468
Influence of different colour plastic mulches
used for soil solarization on the effectiveness
of soil heating. 1st Int. Conf. on Soil
Solarization 297-302.
3. Blok W.J., Lamers J.G., Termorshuizen A.
and Bollen G.J. (2000). Control of soilborne
plant pathogens by incorporating fresh
organic amendments followed by tarping
Phytopathology 90: 253-259.
4. Campiglia E., Temperini O., Mancinelli R.
and Saccardo F. (2000). Effects of soil
solarization on the weed control of vegetable
crops and on the cauliflower and fennel
production in the open field. Acta Hort. 533:
249-255.
5. Cascone G. and D'Emilio A. (2000).
Effectiveness of greenhouse soil solarization
with different plastic mulches in controlling
corky root and knot-rot on tomato plants. Acta
Hort. 532: 145 -150.
6. Chakrabarti B., Wontner-Smith T. and Bell,
C. H. (1995). Reducing methyl bromide
emissions from soil fumigation in
greenhouses. pp 25-1 to 25-3. In: Annual
International Research Conference on Methyl
Bromide Alternatives and Emissions
Reductions. Methyl Bromide Alternatives
Outreach, Fresno, CA.
7. Chaube H.S. and Singh U.S. (1991). Plant
Disease Management: Principle and Practices.
C.R.C. Press F.L., U.S.A. 329 pp.
8. Chauhan Y.S., Nene Y.L., Johansen C.,
Haware M.P., Saxena N.P., Singh S., Sharma
S.B., Sahrawat K.L., Burford J.R., Rupela
O.P., Kumar J.V., Rao O.K. and
Sithanantham S. (1988). Effect of soil-
solarization on pigeonpea and chickpea.
Research Bulletin II. ICRISAT Patancheru.
16pp.
9. Chellemi D.O. (2006). Effect of urban plant
debris and soil management practices on plant
parasitic nematodes, Phytophthora blight and
Pythium root rot of bell pepper. Crop
Protection 25:1109–1116.
10. Chellemi D.O., Olson S.M., Mitchell D.J.,
Secker I. and McSorley R. (1997). Adaptation
of soil solarization to the integrated
management of soilborne pests of tomato
under humid conditions. Phytopathology 87
(3): 250-258.
11. Chen Y., Katan J., Gamliel A., Aviad T. and
Schnitzer M. (2000). Involvement of soluble
organic matter in increased plant growth in
solarized soils. Biol. Fert. Soils 32, 28-34.
12. DeVay J.E. (1991). Use of soil solarization
for control of fungal and bacterial plant
pathogens including biocontrol. In: Proc.
FAO Plant Prod. Prot. Paper 109: 79-93.
13. Elad Y., Katan J. and Chet I. (1980). Physical,
biological and chemical control integrated for
soil-borne disease in potatoes. Phytopathology
70: 418-422.
14. Freeman S. and Katan J. (1988). Weakening
effect on propagules of Fusarium by sublethal
heating. Phytopathology 78: 1656-1616.
15. Gamliel A. and Katan J. (2012). Soil
Solarization: Theory and Practice
16. Gamliel, A. and Katan, J. (1992). Influence of
seed and root exudates on fluorescent
pseudomonads and fungi in solarized soil.
Phytopathology 82: 320-327.
17. Gan J., Yates S.R., Wang D., and Ernst F.F.
1995. Reducing fumigant volatilization
through optimized application and soil
management. pp 26-1 to 26-2 In: Annual
International Research Conference on Methyl
Bromide Alternatives and Emissions
Reductions: Methyl Bromide Alternatives
Outreach, Fresno, CA.
18. Gasoni, L., Kahn N., Yossen V., Cozzi J.,
Kobayashi K., Babbit S., Barrera V. and
Zumelzu G.(2008). Effect of soil solarization
and biocontrol agents on plant stand and yield
on table beet in Córdoba (Argentina). Crop
Protection 27 (3-5): 337-342.
19. Katan J. (1987). Soil solarization. In:
Innovative approaches to plant disease
control. Chet I. (ed). John Wiley and Sons,
New York.
20. Katan J. and DeVay J.E. 1991. Mechanism of
pathogen control in solarized soils. Soil
Solarization. pp 87-101. CRC Press, Boca
Raton, FL.
21. Khulbe D., Chaube H.S. and Sharma J.
(2001). Soil Solarization: An Eco-friendly
approach to raise healthy seedlings of
Horticultural Crops. In: Sinha A.; (ed.)
Microbes and Plants. pp 158-187.Campus
Books, New Delhi, India.
22. Lamichhane J.R., Durr C., Schwanck A.A.,
Robin M.H., Sarthou J.P., Cellier V., Messean
A. and Aubertot, J.N. (2017). Integrated
Int.J.Curr.Microbiol.App.Sci (2019) 8(2): 1456-1469
1469
management of damping-off diseases: A
review. Agron. Sustain. Dev. 37 (2), 25 p.
23. Lifshitz R., Tabachnik M., Katan J. and Chet
I. (1983). The effect of sublethal heating on
sclerotia of Sclerotium rolfsii. Can. J.
Microbiol. 29: 1607-1610.
24. Mahrer Y. (1991). Physical principles of solar
heating of soils by plastic mulching in the
field and in glasshouses and simulation
models. In: Katan J., DeVay J.E. (eds). Soil
solarization. CRC Press, Boca Raton, Florida.
25. Menzies J.D. (1963). Survival of microbial
plant pathogens in soil. Bot. Rev. 29:79–122.
26. Minuto A., Migheli Q., Garibaldi A. and
Vanachter A. (1995). Integrated control of
soilborne plant pathogens by solar heating and
antagonistic microorganisms. Acta. Hort. 382:
138-143.
27. Minuto A., Spadaro D., Garibaldi A. and
Gullino M.L. (2005). Control of soilborne
pathogens of tomato using a commercial
formulation of Streptomyces griseoviridis and
solarization. Crop Protection 25 (5): 468–475.
28. Mishra D.S. (1997). Effect of soil solarization
and its integration with fungicide and
biocontrol agents on microbial population and
seeding diseases of some vegetable crops. M.
Sc. Thesis. G. B. Pant Univ. Ag. &Tech.,
Pantnagar. 53.
29. Nair S.K., Peethambaran C.K., Geetha D.,
Nayar K. and Wilson K.I. (1990). Effect of
soil solarization on nodulation, infection by
mycorrhizal fungi and yield of cowpea. Pl.
Soil 125: 153-154.
30. Rao V.K. and Krishnappa K. (1995).
Integrated management of Meloidogyne
incognita, Fusarium oxysporum f.sp. cireri
wilt disease complex in chickpea. Int. J. Pest
Management 41: 234-237.
31. Rodrigo G., Smith A., Chaves B., Wyckhuys
K., Forero C. and Jiménez J. (2009).
Combined efficacy assessment of soil
solarization and bio-fungicides for
management of Sclerotinia spp. in lettuce
(Lactuca sativa L.) Agronomia Colbiana
27(2): 193-201.
32. Rosskopf E.N., Kokalis-Burelle N.,
Fennimore S.A. and Wilen C.A. (2015).
Soil/Media disinfestation for management of
florists’ crops diseases. Handbook of florists'
crops diseases, pp 1-33.
33. Sainamole K.P., Backiyarain S. and Rajkumar
J. (2003). Effect of soil solarization on plant
growth promotion. In: Reddy M.S., Anandaraj
M., Sarma Y.R. and Kloepper J.W. (eds).
Proceedings of 6th International PGPR
Workshop, Indian Spices Society, Calicut,
Kerala.
34. Stapleton J.J. and DeVay J.E. (1984) Thermal
components of soil solarization as related to
changes in soil and root microflora and
increased plant growth response.
Phytopathology 74: 255–259.
35. Stapleton J.J. and DeVay J.E. (1982). Effect
of soil solarization on population of selected
soilborne microorganisms and growth of
deciduous fruit tree seedlings. Phytopathology
72: 323-326.
36. Stapleton J.J., Quick J., DeVay J.E. (1985)
Soil solarization: effect on soil properties,
fertilization, and plant growth. Soil Biol.
Biochem. 17:369–373.
37. Stapleton J. J. (1997). Soil solarization an
alternative soil disinfestation strategy comes
of age. Sustainable Agriculture. 9: 7-9.
38. Stapleton J.J. and DeVay J.E. (1995). Soil
solarization: A natural mechanism of
integrated pest management. Pages 309-322.
In: Innovative Approaches to Integrated Pest
Management. Reuveni R. (ed). CRC Press,
Boca Raton, Florida.
How to cite this article:
Deepa Khulbe. 2019. Integrating Soil Solarization and Seed Biopriming to Manage Seedling
Damping-Off in Flower Nurseries. Int.J.Curr.Microbiol.App.Sci. 8(02): 1456-1469.
doi: https://doi.org/10.20546/ijcmas.2019.802.169